Response of skeletal muscle UCP2-expression during metabolic adaptation to caloric restriction

Background/objectives Spendthrift vs. thrifty individuals expend more energy and experience greater weight loss during caloric restriction (CR). Adaptive mechanisms in skeletal muscle, adipose tissue, and on hormone level modulate energy expenditure (EE) during weight loss. Metabolic mechanisms underlying the variability in EE during CR are unclear. The present study explored whether during long-term CR (i) gene expression changes in skeletal muscle and adipose tissue relate with the individual EE response and weight loss, and (ii) altered catecholamine and FGF21-concentrations are associated with measures of metabolic adaptation. Subjects/methods In a 10-week inpatient study, 24-h EE was measured before and after 6 weeks of 50% CR in 12 subjects using whole-room indirect calorimetry. Weight loss was assessed and repeated hormone measurements performed. Muscle and adipose tissue biopsies were taken before and after CR, and gene expression was assessed (RNA-Seq). Genes showing the most significant changes after CR were tested for association with EE and followed-up for further association with metabolic measures in a separate phenotyping study ( n = 103). Results Muscle UCP2 showed the strongest change after CR (log 2 -fold change = −1.57, false discovery rate = 0.10) and was considered the best gene for exploration of metabolic adaptive processes. A greater decrease in UCP2 -expression was associated with less weight loss ( P = 0.03, r = 0.77) and relatively lower 24-h EE after CR ( P = 0.001, r = −0.96). Post-CR changes in FGF21-plasma concentrations correlated with UCP2 -expression change ( P = 0.02, r = −0.89) and weight loss ( P = 0.003, r = −0.83). In a separate metabolic phenotyping study, muscle UCP2 -expression correlated with respiratory quotient and macronutrient oxidation. In adipose tissue, no candidate genes for metabolic exploration were found. Conclusions Changes in muscle UCP2 -expression reflect an inter-individual metabolic response to long-term CR and may influence EE and weight loss via modulation of substrate oxidation.